Turnover of phosphatidylglycerol in Streptococcus sanguis

Lipoteichoic acids, phosphate-containing polymers in the envelope of gram-positive bacteria

Lipoteichoic acids (LTA) are polymers of alternating units of a polyhydroxy alkane, including glycerol and ribitol, and phosphoric acid, joined to form phosphodiester units that are found in the envelope of Gram-positive bacteria. Here we review four different types of LTA that can be distinguished on the basis of their chemical structure and describe recent advances in the biosynthesis pathway for type I LTA, d-alanylated polyglycerol-phosphate linked to di-glucosyl-diacylglycerol. The physiological functions of type I LTA are discussed in the context of inhibitors that block their synthesis and of mutants with discrete synthesis defects. Research on LTA structure and function represents a large frontier that has been investigated in only few Gram-positive bacteria.

Enzymatic activities and functional interdependencies of Bacillus subtilis lipoteichoic acid synthesis enzymes

Lipoteichoic acid (LTA) is an important cell wall polymer in Gram-positive bacteria. The enzyme responsible for polyglycerolphosphate LTA synthesis is LtaS, first described in Staphylococcus aureus. Four LtaS orthologues, LtaS_BS, YfnI, YqgS and YvgJ, are present in Bacillus subtilis. Using an in vitro enzyme assay, we determined that all four proteins are Mn²⁺-dependent metal enzymes that use phosphatidylglycerol as a substrate. We show that LtaS_BS, YfnI and YqgS can produce polymers, suggesting that these three proteins are bona-fide LTA synthases while YvgJ functions as an LTA primase, as indicated by the accumulation of a GroP-Glc₂-DAG glycolipid. Western blot analysis of LTA produced by ltaS_BS, yfnI, yqgS and yvgJ single, triple and the quadruple mutant, showed that LTA production was only abolished in the quadruple and the YvgJ-only expressing mutant. B. subtilis strains expressing YfnI in the absence of LtaS_BS produced LTA of retarded mobility, presumably caused by an increase in chain length as suggested by a structural analysis of purified LTA. Taken together, the presented results indicate that the mere presence or absence of LTA cannot account for cell division and sporulation defects observed in the absence of individual enzymes and revealed an unexpected enzymatic interdependency of LtaS-type proteins in B. subtilis.

In vitro analysis of the Staphylococcus aureus lipoteichoic acid synthase enzyme using fluorescently labeled lipids

Lipoteichoic acid (LTA) is an important cell wall component of Gram-positive bacteria. The key enzyme responsible for polyglycerolphosphate lipoteichoic acid synthesis in the Gram-positive pathogen Staphylococcus aureus is the membrane-embedded lipoteichoic acid synthase enzyme, LtaS. It is presumed that LtaS hydrolyzes the glycerolphosphate head group of the membrane lipid phosphatidylglycerol (PG) and catalyzes the formation of the polyglycerolphosphate LTA backbone chain. Here we describe an in vitro assay for this new class of enzyme using PG with a fluorescently labeled fatty acid chain (NBD-PG) as the substrate and the recombinant soluble C-terminal enzymatic domain of LtaS (eLtaS). Thin-layer chromatography and mass spectrometry analysis of the lipid reaction products revealed that eLtaS is sufficient to cleave the glycerolphosphate head group from NBD-PG, resulting in the formation of NBD-diacylglycerol. An excess of soluble glycerolphosphate could not compete with the hydrolysis of the fluorescently labeled PG lipid substrate, in contrast to the addition of unlabeled PG. This indicates that the enzyme recognizes and binds other parts of the lipid substrate, besides the glycerolphosphate head group. Furthermore, eLtaS activity was Mn(2+) ion dependent; Mg(2+) and Ca(2+) supported only weak enzyme activity. Addition of Zn(2+) or EDTA inhibited enzyme activity even in the presence of Mn(2+). The pH optimum of the enzyme was 6.5, characteristic for an enzyme that functions extracellularly. Lastly, we show that the in vitro assay can be used to study the enzyme activities of other members of the lipoteichoic acid synthase enzyme family.

Cell wall assembly in Bacillus subtilis: how spirals and spaces challenge paradigms

Although the bacterial cell wall has been the subject of decades of investigation, recent studies continue to generate novel and controversial models of its synthesis and assembly. Here we compare and contrast the transcompartmental biosyntheses of peptidoglycan and teichoic acid in Bacillus subtilis. In addition, the current paradigms of B. subtilis wall assembly and structure are distinguished from emerging models of murein insertion and organization. We discuss evidence for the directed, cytoskeleton-dependent insertion of nascent peptidoglycan and the existence of a periplasmic compartment. Furthermore, we summarize the challenges these findings represent to the existing paradigm of murein insertion. Finally, motivated by these new developments, we discuss outstanding issues that remain to be addressed and suggest research directions that may contribute to a better understanding of cell wall assembly in B. subtilis.

Isomalto-oligosaccharide-containing lipoteichoic acid of Streptococcus sanguis. Microheterogeneity and distribution of chain substituents

The lipoteichoic acid of Streptococcus sanguis DSM 20567 contains a poly(glycerophosphate) chain, with 49% of the glycerophosphate residues being substituted with D-alanine ester, 35% with alpha-D-glucopyranosyl and alpha-isomalto-oligosaccharide residues. Analysis of molecular species by affinity chromatography on concanavalin A showed all chains to be substituted and alanine ester and glycosyl residues to be present on the same rather than on separate chains. Molecular species varied in the length of the poly(glycerophosphate) chain, the extent of glycosylation, and had a constant alanine-ester content. An alkali-hydrolysis procedure revealed a distribution pattern between random and regular for the glycosyl substituents and suggested a similar distribution for the alanyl residues which occupy the free positions between the glycosyl substituents.

Biosynthesis and characterization of phosphatidylglycerophosphoglycerol, a possible intermediate in lipoteichoic acid biosynthesis in Streptococcus sanguis

A membrane enzyme preparation from Streptococcus sanguis was shown to convert sn-[14C]glycerol 3-phosphate and CDP-diacylglycerol (or deoxyCDP-diacylglycerol) into a series of progressively higher-molecular-weight [14C]oligophosphoglycerophospholipids in vitro. The first oligophosphoglycerophospholipid to accumulate (termed lipid-1) was purified to homogeneity; chemical analysis, gas-liquid chromatography and chemical degradation studies indicated the most likely structure to be phosphatidylglycerophosphoglycerol (PGpG). PGpG is formed directly from two molecules of phosphatidylglycerol (PG), one molecule of PG serving as a sn-glycerol 1-phosphate (pG) donor and the second serving as the pG acceptor, with co-production of diacylglycerol. These oligophosphoglycerophospholipids may be intermediates in the biosynthesis of lipoteichoic acids.

Effect of 3,4-dihydroxybutyl-1-phosphonate on cardiolipin synthesis in B. subtilis

Endogenous phosphatidylglycerol is rapidly transformed into cardiolipin when B. subtilis 168 cells were incubated in a buffer without an energy source. Upon addition of 3,4-dihydroxybutyl-1-phosphonate (DHBP), a synthetic glycerol 3-phosphate analogue, this synthesis was completely blocked after a short lag; if the cells were grown in the presence of the analogue, there was no lag. When membrane fractions were incubated with exogenous [32P]phosphatidylglycerol, free DHBP and glycerol 3-phosphate had no effect on [32P]cardiolipin synthesis, but phosphatidyl-DHBP and phosphatidylglycerolphosphate were potent inhibitors. These results are consistent with our hypothesis that phosphatidylglycerolphosphate, the phosphatidylglycerol precursor, might also be a physical inhibitor of cardiolipin synthesis.

Biosynthesis of the wall acidic polysaccharide in Bacillus cereus AHU 1356

Biosynthetic studies on an acidic polysaccharide, comprising galactose, rhamnose, N-acetylglucosamine and sn-glycerol 1-phosphate, were carried out with a membrane system obtained from Bacillus cereus AHU 1356. Incubation of the membranes with UDP-[14C]Gal, TDP-[14C]Rha and UDP-[14C]GlcNAc resulted in the formation of four or more labeled-sugar-linked lipids and a labeled polysaccharide. Data on structural analysis of the sugar moieties released from the glycolipids, together with results of enzymatic conversion of [14C]galactose-linked lipid and [14C]Rha-Gal-linked lipid to higher-oligosaccharide-linked lipids and polysaccharide, led to the conclusion that the acidic polysaccharide is probably synthesized through the following pathway: (sequence in text) The glycerophosphate residues seem to be derived from phosphatidylglycerol.

Use of resistant mutants to study the interaction of triton X-100 with Staphylococcus aureus

Staphylococcus aureus mutants resistant to the nonionic detergent Triton X-100, isolated from the wild-type strain H and the autolysin-deficient strain RUS3, could grow and divide in broth containing 5% (vol/vol) Triton X-100, while growth of the parental strains was markedly inhibited above the critical micellar concentration (0.02%) of the detergent. Growth-inhibitory concentrations of Triton X-100 killed wild-type cells without demonstrable cellular lysis. Triton X-100 stimulated autolysin activity of S. aureus cells under nongrowing conditions, and this lytic response was markedly reduced in energy-poisoned cells. In contrast, the detergent had no effect on the activity of autolysins in cell-free systems, and growth in the presence of Triton X-100 did not alter either the cellular autolysin activity or the susceptibility of cell walls to exogenous lytic enzymes. Treatment with either Triton X-100 or penicillin G in the growth medium stimulated release of predominantly acylated intracellular lipoteichoic acid and sensitized staphylococci to Triton X-100-induced autolysis. There was no significant difference in the cell wall and membrane compositions or Triton X-100 binding between the parental strains and the resistant mutants. The resistant mutant TXR1, derived from S. aureus H, had a higher level of L-alpha-glycerophosphate dehydrogenase activity, and its oxygen uptake was more resistant to inhibition by a submicellar concentration (0.008%) of Triton X-100. Growth in the presence of subinhibitory concentrations of Triton X-100 rendered S. aureus H cells phenotypically resistant to the detergent and greatly stimulated the level of oxygen uptake. Membranes isolated from such cells exhibited enhanced activity of the respiratory enzymes succinic dehydrogenase and L-alpha-glycerophosphate dehydrogenase.

Phosphatidylglycerol as biosynthetic precursor for the poly(glycerol phosphate) backbone of bifidobacterial lipoteichoic acid

Phosphatidylglycerol functions as donor of the sn-glycerol 1-phosphate units in the synthesis in vitro of the 1,2-phosphodiester-linked glycerol phosphate backbone of the lipoteichoic acids of Bifidobacterium bifidum subsp. pennsylvanicum. The incorporation was catalysed by a membrane-bound enzyme system. After addition of chloroform/methanol the product formed coprecipitated with protein. The material was phenol-extractable and was co-eluted with purified lipoteichoic acid on Sepharose 6B. The reaction was stimulated by Triton X-100, UDP-glucose and UDP-galactose, but Mg2+ ions had no effect. The apparent values for Km and Vmax. of the phosphatidylglycerol incorporation were 1.4 mM and 3.1 nmol/h per mg of membrane protein, respectively. Labelled UDP-glucose and UDP-galactose were not incorporated into the lipoteichoic acid fraction by the particulate membrane preparation.

Phosphatidyl glycerolphosphate serves as glycerolphosphate donor in polymer synthesis

Phosphatidyl glycerolphosphate was found to serve as the glycerolphosphate donor for polymer synthesis. When CDP-diglyceride and radiolabeled glycerolphosphate were incubated with the membrane enzyme prepared from Streptococcus sanguis, active syntheses of radiolabeled lipids and polymers were observed. The synthesis of polymer was not inhibited by low concentration of unlabeled phosphatidylglycerol. When [3H, 32P]glycerolphosphate was used, the polymer synthesized contained both 3H and 32P. The lipids formed were characterized as phosphatidylglycerol and phosphatidyl glycerolphosphate. The polymers formed from the latter were characterized as lipoteichoic acid like compounds by sodium dodecylsulfate-polyacrylamide gel electrophoresis.

Synthesis of peptidoglycan and teichoic acid in Bacillus subtilis: role of the electrochemical proton gradient

The effects of several ionophores and uncouplers on glycerol and N-acetylglucosamine incorporation by Bacillus subtilis 61360, a glycerol auxotroph, were tested at different pH values. In particular, the effect of valinomycin on the synthesis of teichoic acid and peptidoglycan was examined in more detail in both growing cells and in vitro biosynthetic systems. Valinomycin inhibited synthesis of wall teichoic acid and peptidoglycan in whole cells but not in the comparable in vitro systems. It did not inhibit formation of free lipid or lipoteichoic acid. The results were consistent with a role for the electrochemical proton gradient in maintaining full activity of cell wall synthetic enzymes in intact cells. Such an energy source would be required for a model in which rotation or reorientation of synthetic enzyme complexes is envisaged for the translocation of wall precursor molecules across the cytoplasmic membrane (Harrington and Baddiley, J. Bacteriol. 155:776-792, 1983).

The role of lipoteichoic acid biosynthesis in membrane lipid metabolism of growing Staphylococcus aureus

Pulse-chase experiments with [2-3H]glycerol and [14C]acetate revealed that in Staphylococcus aureus lipoteichoic acid biosynthesis plays a dominant role in membrane lipid metabolism. In the chase, 90% of the glycerophosphate moiety of phosphatidylglycerol was incorporated into the polymer: 25 phosphatidylglycerol + diglucosyldiacylglycerol leads to (glycerophospho)25-diglucosyldiacylglycerol + 25 diacylglycerol. Glycerophosphodiglucosyldiacylglycerol was shown to be an intermediate, confirming that the hydrophilic chain is polymerized on the final lipid anchor. Total phosphatidylglycerol served as the precursor pool and was estimated to turn over more than twice for lipoteichoic acid synthesis in one bacterial doubling. Of the resulting diacylglycerol approximately 10% was used for the synthesis of glycolipids and the lipid anchor of lipoteichoic acid. The majority of diacylglycerol recycled via phosphatidic acid to phosphatidylglycerol. Synthesis of bisphosphatidylglycerol was negligible and only a minor fraction of phosphatidylglycerol passed through the metabolically labile lysyl derivative. In contrast to normal growth, energy deprivation caused an immediate switch-over from the synthesis of lipoteichoic acid to the synthesis of bisphosphatidylglycerol.

Lipopolymers, isoprenoids, and the assembly of the gram-positive cell wall

Several lines of evidence suggest that Gram-positive bacterial cell surface polymers are synthesized by stepwise addition of polymer subunits to an amphipathic acceptor. In the case of membrane-bound lipopolymers such as mannan and lipoteichoic acid, the finished product may be covalently linked to a lipid anchor. In the case of polymers that are transferred into preexisting cell wall, such as teichoic acid and peptidoglycan, two alternative fates might be possible: (1) transfer into wall with concomitant or later cleavage of the lipid anchor, with recycling of the lipid anchor or secretion of the lipid anchor into the growth medium, and (2) transfer into wall without cleavage of the lipid anchor, resulting in maintenance of the covalent relationship between lipid anchor and polymer chain. In the latter case, a close relationship should be established between the cell wall and the plasma membrane. A number of Gram-positive bacteria have been shown to be resistant to plasmolysis. Therefore, a model for the assembly of the Gram-positive cell wall is proposed which takes into account a role for lipopolymeric intermediates and which views the establishment of resistance to plasmolysis as the natural consequence of such a mechanism.

Biosynthesis of D-alanyl-lipoteichoic acid: role of diglyceride kinase in the synthesis of phosphatidylglycerol for chain elongation

Lipophilic and hydrophilic D-alanyl-lipoteichoic acids are elongated in Lactobacillus casei by the transfer of sn-glycerol 1-phosphate units from phosphatidylglycerol to the poly(glycerophosphate) moiety of the polymer. These sn-glycerol 1-phosphate units are added to the end of the poly(glycerophosphate) which is distal to the glycolipid anchor; 1,2-diglyceride results from this addition. The presence of a diglyceride kinase was suggested by the ATP-dependent phosphorylation of 1,2-diglyceride to phosphatidic acid. Inorganic phosphate was used to initiate the synthesis of lipophilic lipoteichoic acid (LTA) and the elongation of both lipophilic and hydrophilic LTA. Three observations suggest that phosphate and other anions play a role in the in vitro synthesis of LTA and its precursors. First, the conversion of 1,2-diglyceride to phosphatidic acid by diglyceride kinase was stimulated. Second, the synthesis of phosphatidylglycerol was increased. Third, the elongation of lipophilic and hydrophilic LTA was enhanced. These observations indicated that one effect of phosphate might be to enhance the utilization of 1,2-diglyceride for the synthesis of phosphatidic acid. This phospholipid is a precursor of phosphatidylglycerol, the donor of sn-glycerol 1-phosphate for elongation of LTA.

Products of phospholipid metabolism in Bacillus stearothermophilus

The products of phospholipid turnover in Bacillus stearothermophilus were determined in cultures labeled to equilibrium and with short pulses of [32P]phosphate and [2-3H]glycerol. Label lost from the cellular lipid pool was recovered in three fractions: low-molecular-weight extracellular products, extracellular lipid, and lipoteichoic acid (LTA). The low-molecular-weight turnover products were released from the cells during the first 10 to 20 min of a 60-min chase period and appeared to be derived primarily from phosphatidylglycerol turnover. Phosphatidylethanolamine, which appeared to be synthesized in part from the phosphatidyl group of phosphatidylglycerol, was released from the cell but was not degraded. The major product of phospholipid turnover was LTA. Essentially all of the label lost from the lipid pool during the final 40 min of the chase period was recovered as extracellular LTA. The LTA appeared to be derived primarily from the turnover of cardiolipin and the phosphatidyl group of phosphatidylglycerol. Three types of LTA were isolated; an extracellular LTA was recovered from the culture medium, and two types of LTA were extracted from membrane preparations or whole-cell lysates by the hot phenol-water procedure. Cells contained 1.5 to 2.5 mg of cellular LTA per g of cells (dry weight), over 50% of which remained associated with the membrane when cells were fractionated. Over 75% of the 3H label incorporated into the cellular LTA pool during a 90-min labeling period was released from the cells during the first cell doubling after the chase. Label lost from the lipid pool was incorporated into cellular LTA which was then modified and released into the culture medium.

Biosynthesis of glucosyl monophosphoryl undecaprenol and its role in lipoteichoic acid biosynthesis

A glucophospholipid was detected in an incubation mixture containing UDP-glucose, MgCl2, ATP, and a particulate enzyme prepared from Streptococcus sanguis. The synthesis of this lipid was inhibited strongly by UDP and moderately by UMP. The molar ratio of glucose to phosphate in the purified lipid was found to be 1:1. Glucose and glucose 1-phosphate were released by mild alkaline hydrolysis of the glucophospholipid. The lipid produced by mild acid degradation of the purified lipid yielded a thin-layer chromatographic profile similar to that of acid-treated undecaprenol. One of the minor components exhibited the same mobility as untreated undecaprenol. To characterize further the lipid moiety of the glucophospholipid, a polyisoprenol was purified from the neutral lipid of S. sanguis. The polyisoprenol was converted in the presence of ATP, UDP-glucose, and the particulate enzyme into a lipid which exhibited the same thin-layer chromatographic mobility as the glucophospholipid. The structure of the polyisoprenol was determined by nuclear magnetic resonance and mass spectrometry to be an undecaprenol with an internal cis-trans ratio of 7:2. These results indicate that the glucophospholipid is glucosyl monophosphoryl undecaprenol. The glucosyl moiety of the glucophospholipid was shown to be incorporated in the presence of the particulate enzyme into a macromolecule which was characterized as a lipoteichoic acid by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and DEAE-cellulose column chromatography. This result indicates that glucosyl monophosphoryl undecaprenol is the direct glucosyl donor in the synthesis of lipoteichoic acid.

Effects of penicillin on synthesis and excretion of lipid and lipoteichoic acid from Streptococcus mutans BHT

Cultures of Streptococcus mutans BHT grown for at least eight generations in a chemically defined medium containing [1(3)-14C]glycerol, when treated with growth-inhibitory concentrations (0.2 micrograms/ml) of benzylpenicillin (Pen G), produced and excreted increased amounts of lipid and lipoteichoic acid per unit of cells. Cellular lysis was not observed. Compared with untreated controls, lipid excretion increased 15-fold, and lipoteichoic acid excretion increased 6-fold, 4 h after the addition of Pen G. All lipid species showed increased synthesis and excretion after exposure to Pen G. Although the same lipid types were found in both the Pen G-treated and the untreated cultures, the percent composition was altered after treatment with Pen G. The most dramatic example of this was the percentage of intracellular diphosphatidylglycerol found in the Pen G-treated cultures, 22.6%, in contrast to 5.3% found in the untreated cultures.

Teichoic and teichuronic acids: biosynthesis, assembly, and location

Images

Effect of cerulenin on cellular autolytic activity and lipid metabolism during inhibition of protein synthesis in Streptococcus faecalis

Cellular autolytic activity as well as lipid and lipoteichoic acid metabolism have been studied in cultures of Streptococcus faecalis receiving various combinations of the following treatments: chloramphenicol addition, starvation for an essential amino acid (valine), and cerulenin treatment. Lipoteichoic acid initially accumulated in chloramphenicol-treated and amino acid-starved cells and decreased relative to the cellular mass in cerulenin-treated cells. The relative phosphatidylglycerol content of amino acid-starved cultures or of cultures treated with either antibiotic rapidly decreased upon initiation of each treatment. In all cases, cerulenin initially stimulated diphosphatidylglycerol synthesis. Pretreatment of cultures with cerulenin prevented the inhibition of cellular synthesis autolysis normally observed during chloramphenicol treatment, but did not affect amino acid starvation-induced inhibition of autolytic activity. Variations in the levels of the nonionic lipid fraction, predominantly diglycerides, correlated best with the patterns of autolytic activity observed during chloramphenicol treatment, whereas variations in the levels of diphosphatidylglycerol and lipoteichoic acid correlated best with the patterns of autolytic activity observed during amino acid starvation. Components of the nonionic lipid fraction were demonstrated to inhibit autolytic activity 50% in whole cell and in cell wall assays at 60 and 120 nmol/mg (dry weight), respectively.

Biosynthesis of D-alanyl-lipoteichoic acid in Lactobacillus casei: D-alanyl-lipophilic compounds as intermediates

D-Alanyl-lipoteichoic acid (D-alanyl-LTA) from Lactobacillus casei contains a poly(glycerol phosphate) moiety that is selectively acylated with D-alanine ester residues. To characterize further the mechanism of D-alanine substitution, intermediates were sought that participate in the assembly of this LTA. From the incorporation system utilizing either toluene-treated cells or a combination of membrane fragments and supernatant fraction, a series of membrane-associated D-[14C]alanyl-lipophilic compounds was found. The assay of these compounds depended on their extractability into monophasic chloroform-methanol-water (0.8:3.2:1.0, vol/vol/vol) and subsequent partitioning into chloroform. Four lines of evidence suggested that the D-alanyl-lipophilic compounds are intermediates in the synthesis of D-alanyl-LTA. First, partial degradation of the poly(glycerol phosphate) moiety of D-alanyl-LTA by phosphodiesterase II/phosphatase from Aspergillus niger generated a series of D-alanyl-lipophilic compounds similar to those extracted from the toluene-treated cells during the incorporation of D-alanine. Second, enzymatic degradation of the D-alanyl-lipophilic compounds by the above procedure gave D-alanyl-glycerol, the same degradation product obtained from D-alanyl-LTA. Third, the incorporation of D-alanine into these compounds required the same components as the incorporation of D-alanine into membrane-associated D-alanyl-LTA. Fourth, the phosphate-induced loss of D-[14C]alanine-labeled lipophilic compounds could be correlated with the stimulation of phosphatidylglycerol synthesis in the presence of excess phosphate. We interpreted these experiments to indicate that the D-alanyl-lipophilic compounds are D-alanyl-LTA with short polymer chains and are most likely intermediates in the assembly of the completed polymer, D-alanyl-LTA.

Two distinct pools of membrane phosphatidylglycerol in Bacillus megaterium

The predominant membrane lipid in Bacillus megaterium ATCC 14581, phosphatidylglycerol (PG), is present in two distinct pools, as shown by [32P]phosphate incorporation and chase experiments. One pool (PGt) undergoes rapid turnover of the phosphate moiety, whereas the second pool (PGs) exhibits metabolic stability in this group. The phosphate moiety of the other major phospholipid, phosphatidylethanolamine, is stable to turnover. [32P]phosphate- and [2-3H]glycerol-equilibrated cultures yielded the following glycerolipid composition: 56 mol% PG (34 mol% PGt and 22 mol% PGs), 21 mol% phosphatidylethanolamine, 1 to 2 mol% phosphatidylserine, 20 mol% diglycerides, less than 0.5 mol% cardiolipin, and 0.2 to 0.4 mol% lysophosphatidylglycerol. Accumulation of PG was halted immediately after the addition of cerulenin, an inhibitor of de novo fatty acid synthesis, whereas phosphatidylethanolamine accumulation continued at the expense of the diglyceride and PG pools. Strikingly, initial rates of [32P]phosphate incorporation into PG were unaffected by cerulenin. In control cultures at 35 degrees C, incorporation of [32P]phosphate into PG exhibited a biphasic time course, whereas incorporation into phosphatidylethanolamine was concave upward and lagged behind that of PG during the initial rapid phase of PG incorporation. Finally, levels of lysophosphatidylglycerol expanded rapidly after cerulenin addition at 20 degrees C, but not at 35 degrees C. Moreover, incorporation of [32P]phosphate into lysophosphatidylglycerol lagged behind incorporation into PG in both the presence and absence of cerulenin at 20 and 35 degrees C.

A rapidly metabolizing pool of phosphatidylglycerol as a precursor of phosphatidylethanolamine and diglyceride in Bacillus megaterium

Pulse-chase experiments in Bacillus megaterium ATCC 14581 with [U-14C]palmitate, L-[U-14C]serine, and [U-14C]glycerol showed that a large pool of phosphatidylglycerol (PG) which exhibited rapid turnover in the phosphate moiety (PGt) underwent very rapid interconversion with the large diglyceride (DG) pool. Kinetics of DG labeling indicated that the fatty acyl and diacylated glycerol moieties of PGt were also utilized as precursors for net DG formation. The [U-14C]glycerol pulse-chase results also confirmed the presence of a second, metabolically stable pool of PG (PGs), which was deduced from [32P]phosphate studies. The other major phospholipid, phosphatidylethanolamine (PE), exhibited pronounced lags relative to PG and DG in 14C-fatty acid, [14C]glycerol, and [32P]phosphate incorporation, but not for incorporation of L-[U-14C]serine into the ethanolamine group of PE or into the serine moiety of the small phosphatidylserine (PS) pool. Furthermore, initial rates of L-[U-14C]serine incorporation into the serine and ethanolamine moieties of PS and PE were unaffected by cerulenin. The results provided compelling in vivo evidence that de novo PGt, PS, and PE synthesis in this organism proceed for the most part sequentially in the order PGt yields PS yields PE rather than via branching pathways from a common intermediate and that the phosphatidyl moiety in PS and PE is derived largely from the corresponding moiety in PGt, whereas the DG pool indirectly provides an additional source for this conversion by way of the facile PGt in equilibrium or formed from DG interconversion.

Studies on the relationship between glycerophosphoglycolipids and lipoteichoic acids. IV. Trigalactosylglycerophospho-acylkojibiosyldiacylglycerol and related compounds from Streptococcus lactis Kiel 42172

Streptococcus lactis Kiel 42172 contains at least six unusually polar glycerophosphoglycolipids. The predominant one was composed of D-galactose, D-glucose, glycerol, acyl groups and phosphorus in a molar ratio of approx. 3 : 2 : 2 : 3 : 1. By analysis of the breakdown products of HF hydrolysis and Smith-degradation the structure was established to be [Galp (alpha 1 leads to 6)Galp(alpha 1 leads to 3)-sn-glycero(2 comes from 1 alpha Galp)-1-phospho] leads to 6Glcp(alpha 1 leads to 2), acyl leads to Glcp(alpha 1 leads to 3)-acyl2Gro. By HF hydrolysis the other compounds were shown to be in the main also derivatives of GroP leads to 6Glc(alpha 1 leads to 2), acyl leads to 6Glc(alpha 1 leads to 3)acyl2Gro but they released as water-soluble glycosides Gal(alpha 1 leads to 2)Gro, Gal(alpha 1 leads to 3)Gro, Gal(alpha 1 leads to 3)Gro(2 comes from 1 alpha Gal), Gal(alpha 1 leads to 6)Gal(alpha 1 leads to 3)Gro and Gal(alpha 1 leads to 6)Gal-(alpha 1 leads to 6)Gal(alpha 1 leads to 3)Gro(2 comes from 1 alpha Gal), respectively. In the lipid extract Glc(alpha 1 leads to 2), acyl leads to 6Glc(alpha 1 leads to 3)acyl2Gro and GroP leads to 6Glc(alpha 1 leads to 2), acyl leads to 6Glc(alpha 1 leads to 3) acyl2Gro were also observed. This set of compounds is proposed to constitute a biosynthetic series reflecting the individual steps in the synthesis of the lipoteichoic acid of Streptococcus lactis Kiel 42172 which is made up by the same lipid anchor and a non-classical poly(galabiosyl, galactosyl glycerophosphate)-chain (Koch, H.U. and Fischer, W. (1978) Biochemistry 17, 5275--5281).

Biosynthesis of phospholipids in Bacillus megaterium

Information on the biosynthesis of phospholipids in bacteria has been derived principally from the study of Escherichia coli and other gram-negative organisms. We have now carried out a detailed study of the pathways of phospholipid biosynthesis in the gram-positive organism Bacillus megarterium KM in relation to investigations on the biogenesis of lipid asymmetry in membranes. Radioactive precursors such as 32Pi and [3H]palmitate initially label phosphatidylethanolamine much more than phosphatidylglycerol. This raised the possibility that phosphatidylglycerol may be the precursor of phosphatidylethanolamine in a pathway different from that in E. coli. Phosphatidylglycerol is known to be highly reactive metabolically, since it functions as a donor of phosphatidyl residues in the synthesis of cardiolipin and as a donor of glycerophosphate residues in the synthesis of teichoic acids and of membrane-derived oligosaccharides. The large pool of phosphatidylglycerol would dilute the radioactive isotope, slowing the initial rate of incorporation of label into phosphatidylethanolamine. However, assays of cell-free extracts revealed no evidence for such a novel pathway. Instead, phosphatidylserine synthase (cytidine 5'-diphosphate-diglyceride:L-serine phosphatidyl transferase) and phosphatidylserine decarboxylase were detected, although at low levels. These results suggest that the pathway in B. megaterium is the same as that in E. coli in which phosphatidylserine, derived from cytidine 5'-diphosphate-diglyceride, is the precursor of phosphatidylethanolamine. The lag in the appearance of label in phosphatidylethanolamine appears to be the effect of a considerable pool of phosphatidylserine (ca. 5 to 10% of the total phospholipid) in certain strains of B. megaterium. The lag in labeling can be correlated with the size of the pool of phosphatidylserine. Pulse-chase experiments in vivo support the conclusion that in B. megaterium phosphatidylserine is not derived from phosphatidylglycerol. Rates of turnover of the membrane phospholipids of B. megaterium have also been studied.

Biosynthesis of glycosylated glycerolphosphate polymers in Streptococcus sanguis

Two types of glycosylated glycerolphosphates were synthesized when a particulate enzyme prepared from Streptococcus sanguis was incubated with [3H]-phosphatidylglycerol and uridine diphosphate-[14C]glucose in the presence of MgCl2. The first type was extractable with saline and contained no fatty acid. The second type was pellet bound and could be extracted with 0.1% sodium dodecyl sulfate. Both types of polymers were purified and partially characterized. The first type of polymer was fractionated into five polymers, peaks 2a, 2b, 2c, 3a, and 3b. All except peak 2a, which contained only [3H]glycerol, contained both [3H]glycerol and [14C]glucose. [3H]NaBH4 reduction of acid hydrolysates of the polymers revealed that all of the polymers contained glucose as the major sugar componenta nd xylose as the minor sugar component. The second type of polymer was fractionated into three polymers, P-1, P-2, and P-3. All contained [3H]-glycerol, [14C]glucose, and fatty acids. P-1 appeared to be pure, whereas P-2 and P-3 contained two polymers each, as judged from sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Precursor-product relationship of intracellular and extracellular lipoteichoic acids of Streptococcus faecium

Exponential biosynthesis and excretion of lipoteichoic acid (LTA) during the exponential phase of growth, and continued synthesis and excretion during valine starvation of Streptococcus faecium (S. faecalis ATCC 9790), were shown. During exponential growth, extracellular LTA (LTAx) accounted for approximately 13% of the total LTA in cultures, whereas during valine starvation, this percentage increased to approximately 60% within 4 h. LTAx was present in a low-molecular-weight, apparently deacylated form, whereas intracellular (LTAi) was present primarily in an apparently high-molecular-weight, acylated and micellar form. Experiments utilizing chases of either fully equilibrated or short pulses of [14C]- or [3H]glycerol were used to demonstrate that LTAx was derived directly from LTAi.

On the relationship between glycerophosphoglycolipids and lipoteichoic acids in Gram-positive bacteria. II. Structures of glycerophosphoglycolipids

1. Eight glycerophosphoglycolipids were isolated from six Gram-positive bacteria. Besides sn-glycero-1-phospho-beta-gentiobiosyldiacylglycerol (i) and sn-glycero-1-phospho-alpha-kojibiosyldiacylglycerol (ii), three novel structures have been established: 1,2-di-O-acyl-3-O-[6-(sn-glycero-1-phospho)-alpha-D-glucopyranosyl-(1 leads to 2)-(6-O-acyl-alpha-D-glucopyranosyl)]glycerol (iii), 1,2-di-O-acyl-3-O-[6-(sn-glycero-1-phospho)-beta-D-glucopyranosyl-(1 leads to 6)-alpha-D-galactopyranosyl-(1 leads to 2)-alpha-D-glucopyranosyl]glycerol (iv), and 1,2-di-O-acyl-3-O-[6-(sn-glycero-1-phospho)-beta-D-glucopyranosyl-(1 leads to 6)-alpha-D-galactopyranosyl-(1 leads to 2)-(6-O-acyl-alpha-D-glucopyranosyl)]glycerol (v). 2. Compound i was isolated from Bacillus licheniformis, Bacillus subtilis and Staphylococcus aureus, compound ii from a group B Streptococcus, compounds ii and iii from Streptococcus lactis, compounds iv and v from Lactobacillus casei. Lactobacillus plantarum contained besides compounds iv and v a glycerophosphate derivative of 1,2-di-O-acyl-3-O-[alpha-D-galactopyranosyl (1 leads to 2)-alpha-D-glucopyranosyl]glycerol. 3. Identical structural features of the described glycerophosphoglycolipids and the corresponding lipoteichoic acids are discussed.

Biosynthesis of oligosaccharide-lipid in Streptococcus sanguis

An oligosaccharide-lipid containing N-acetyl d-glucosamine (GlcNAc), l-rhamnose, and d-glucose was synthesized when the particulate enzyme from Streptococcus sanguis was incubated with UDP-GlcNAc, TDP-rhamnose, and UDP-glucose. The incorporation of d-glucose into the lipid was dependent on the preincorporation of l-rhamnose, which in turn was dependent on that of GlcNAc. This indicates that the order of sugar incorporation is GlcNAc, l-rhamnose, and d-glucose. The synthesis of GlcNAc-lipid was stimulated twofold by ATP and was inhibited strongly by UDP and slightly by UMP, CDP, and TDP, but not by all other nucleoside diphosphates and nucleoside monophosphates tested. A [gamma-(32)P]ATP labeling experiment indicated that some acceptor lipid was present in nonphosphorylated form. The acid and alkaline stabilities of the GlcNAc-lipid were similar to those of glycosyl undecaprenylphosphate, and the thin-layer chromatographic mobility of the lipid was slightly faster than that of the mannosylphosphorylundecaprenol. The molar ratio of phosphate to GlcNAc in purified GlcNAc-lipid was found to be 0.96:1. These results suggested that the GlcNAc was attached to the lipid moiety, presumably undecaprenol, by phosphodiester bonds. The incorporation of l-rhamnose into the lipid was inhibited by UDP and UMP, respectively, in a manner similar to the incorporation of GlcNAc. This suggested that the oligosaccharide was also linked to the lipid moiety by phosphodiester bonds.

Occurrence and function of membrane teichoic acids

Membrane teichoic acids, sometimes described as lipoteichoic acids, are important but not major components of nearly all Gram-positive bacteria. They appear on the outer surface of the cytoplasmic membrane and possess antigenic properties. Several functions have been ascribed to these glycerol phosphate polymers, including the binding of divalent cations required for optimal activity of membrane-bound enzymes, and the control of certain lytic enzymes. A substance that is identical or closely similar to membrane teichoic acid, lipoteichoic acid carrier, plays an important part in the biosynthesis of wall teichoic acid; it accepts polyol phosphate residues from CDP-glycerol or CDP-ribitol to form a polyol phosphate chain which is then transferred after the incorporation of a tri(glycerol phosphate) linkage unit, to the growing glycan chain of peptidoglycan.

Incorporation of 3,4-dihydroxybutyl-1-phosphonate, a glycerol 3-phosphate analogue, into the cell wall of Bacillus subtilis

3,4-Dihydroxybutyl-1-phosphonate, a bacteriostatic agent toward Bacillus subtilus 168 and a bactericidal agent toward strain W 23, is incorporated into cell walls and phospholipids of each strain.

In vitro synthesis of the unit that links teichoic acid to peptidoglycan

The role of cytidine diphosphate (CDP)-glycerol in gram-positive bacteria whose walls lack poly(glycerol phosphate) was investigated. Membrane preparations from Staphylococcus aureus H, Bacillus subtilis W23, and Micrococcus sp. 2102 catalyzed the incorporation of glycerol phosphate residues from radioactive CDP-glycerol into a water-soluble polymer. In toluenized cells of Micrococcus sp. 2102, some of this product became linked to the wall. In each case, maximum incorporation of glycerol phosphate residues required the presence of the nucleotide precursors of wall teichoic acid and of uridine diphosphate-N-acetylglucosamine. In membrane preparations capable of synthesizing peptidoglycan, vancomycin caused a decrease in the incorporation of isotope from CDP-glycerol into polymer. Synthesis of the poly (glycerol phosphate) unit thus depended at an early stage on the concomitant synthesis of wall teichoic acid and later on the synthesis of peptidoglycan. It is concluded that CDP-glycerol is the biosynthetic precursor of the tri(glycerol phosphate) linkage unit between teichoic acid and peptidoglycan that has recently been characterized in S. aureus H.

Formation of extracellular lipoteichoic acid by oral streptococci and lactobacilli

Examination of the culture fluids from a number of strains of oral streptococci and latobacilli has shown the presence of an erythrocyte-sensitizing antigen with the properties of lipoteichoic acid. The antigen was isolated from the culture fluids of Lactobacillus casei and Lactobacillus fermentum and characterized chemically and serologically, For other strains, serological evidence for the presence of lipoteichoic acid depends on the reactivity with antiserum specific for the glycerol phosphate backbone. The relative concentrations of the antigen in culture fluids from different organisms, in culture fluids from different stages of growth, and in extracts of organisms was estimated by determining the maximum dilution that fully sensitized erythrocytes; the culture fluid titer, which is the reciprocal of the dilution, varied from 4 to 320. Strains of Streptococcus mutans were generally characterized by a high level of extracellular lipoteichoic acid, the amount being greater than that detectable in cell extracts; this conclusion was confirmed by using the quantitative precipitin method. A high-molecular-weight fraction obtained from S. mutans BHT culture fluid was effective in sensitizing erythrocytes at a concentration of 1 mug/ml, compared with 2 mug/ml required for cellular lipoteichoic acid from L. casei. The detecting procedure depends on the teichoic acid sensitizing erythrocytes but, as shown with L. fermentum, low-molecular-weight nonsensitizing teichoic acid may also be present in culture fluid.

Glycerophosphoryl phosphatidyl kojibiosyl diacylglycerol, a novel phosphoglucolipid from Streptococcus faecalis

1. From Streptococcus faecalis a third novel phosphoglucolipid was isolated. It contained D-glucose, glycerol, acyl groups and phosphorus in a molar ratio of approx. 2 : 3 : 4 : 2. 2. The structure was shown to be 3(1)-O-[6 inches-(sn-glycerol-1-phosphoryl), 6 foot-(1,2 diacyl-sn-glycerol-3-phosphoryl)-2 foot-O-(alpha-D-glucopyranosyl)-alpha-D-glucopyranosyl]-1(3),2-diacylglycerol. The novel lipid is related to the earlier described phosphatidyl and glycerophosphoryl kojibiosyl diacylglycerol from Streptococcus faecalis by combininb their substituents in its structure. 3. The structure of the deacylated core was accomplished by analyses of the breakdown products obtained on Smith degradation and strong alkaline hydrolysis. The location of the acyl groups was achieved by degradation of the intact lipid with 60% HF (w/v) which resulted in the formation of inorganic phosphate, glycerol, diacylglycerol and diglucosyl diacylglycerol. The sn-glycerol-1-phosphoryl and 3-sn-phosphatidyl substituents were located by hydrolysis of the lipid with 98% acetic acid (v/v) and subsequent analysis of the resultant phosphatidyl diglucosyl diacylglycerol. 4. The composition and positional distribution of the constituent fatty acids at the two diacylglycerol portions was studied by combination of chemical and enzymatic degradations. The fatty acids are the same as with the other polar lipids of S. faecalis, they are present in nearly the same proportions and display the same non-random distribution pattern. 5. A possible relationship between sn-glycerol 1-phosphate containing phosphoglucolipids and lipoteichoic acid will be discussed.

Characterization of the lipids of mesosomal vesicles and plasma membranes from Staphylococcus aureus

Mesosomal vesicles and plasma membranes were isolated from Staphylococcus aureus ATCC 6538P by protoplasting and differential centrifugation. The lipids of each of the two membrane fractions were extracted with pyridine-acetic acid-N-butanol, and the nonlipid contaminants were removed by Sephadex treatment. The lipids were then separated by passage through diethylaminoethyl-cellulose columns and characterized by thin-layer chromatographic, chemical, and spectral analyses. The lipids were separated into four discrete diethylaminoethyl fractions: (i) vitamin K2, carotenoids, C55 isoprenoid alcohol, and monoglucosyl diglyceride; (ii) cardiolipin, carotenoids, phosphatidyl glycerol, diglucosyl diglyceride, and an unidentified ninhydrin-positive component; (iii) cardiolipid and phosphatidyl glyderol; (iv) cardiolipin, phosphatidyl glycerol, and phosphatidyl glucose. Qualitatively, no difference in lipid composition between mesosomal vesicles and plasma membranes was found. However, based on equal dry weights of membrane materials, a relative quantitative difference in the amount of specific lipids in mesosomal vesicles and plasma membranes was observed. There are 4 times more monoglucosyl diglyceride, 2.6 times more diglucosyl diglyceride, 3.8 times more phosphatidyl glucose, 2 times more carotenoids, and 2 times more vitamin K2 found in mesosomal vesicles than in plasma membranes. The concentration of cardiolipin and phosphatidyl glycerol is 3.6 and 6 times greater, respectively, in mesosomal vesicles.